DE2529482A1 - Price computing balance protected against functional errors - has an electronic weight transmission device and multiplier to produce numerical displays - Google Patents

Abstract

The weight is transmitted to a computer to which the unit price is fed. It multiplies one by the other and displays in two numerical displays the weight, the unit price and the calculated price of the goods. A second computer (25) operating synchronously with the first (24) is connected in parallel to the weight transmission device. Computers (24, 25) multiply the weight and unit price by powers of ten, so that the weight, unit price and goods price are consecutive digits of the calculated product, sequentially applied by the computers (24, 25) to one of the two display units (26, 27). Computers (28-34) are inserted between corresponding elements of the two display units. In case of coincidence a following gate is not affected, and in case of non-coincidence the gate trips a following flip-flop.

Description

Functionally error-proof, price-computing scales The invention relates to a functionally error-proof, price-calculating scale with an electronic weight transmission device, to which a computer is connected, in which the basic price is entered, the is multiplied in the calculator with the weight value, and with two digit displays for the weight value, the basic price and the price of the goods calculated from it.

It is an electronically price-calculating commercial scale with double value or numeric display for weight or weight value, basic price and price of goods, on the one hand on the seller side and on the other on the customer side by means of electronic numeric display systems.

Scales to determine the performance in public transport must because of its great economic importance, it must be designed to prevent functional errors first order, in particular in the system of electronic data acquisition and measured value processing, automatically recognized and signaled0 To fulfill Various procedures have been developed for these calibration requirements which, however, require special computers for the respective error control circuit are adapted. In contrast, there is a wide variety of cheaper commercially available Computer elements that are used in desk and pocket calculators, but not Have first-order functional error protection.

The object of the invention is therefore to provide an arrangement which a scale using non-functionally fail-safe computer circuits with measured value acquisition and measured value processing creates that with only a small additional effort is dysfunctional, and thus the advantages affect the large-scale production for the computer circuit.

To solve this problem, the balance according to the invention is characterized in that that to the weight transfer device parallel to the first computer a synchronous is connected to this working second computer that the computer is designed are that the input of weight value and basic price are each by powers of ten is increased so that weight value, base price and price of goods are consecutive Digits of the calculated product are sequential from the calculators respectively one of the two numeric displays are fed, and that between each other equivalent Display elements of the two numeric displays each switched to window discriminators are which, in the event of a match, have no influence on a downstream gate circuit and, in the event of a mismatch, influence the gate circuit in such a way that that a downstream flip-flop switches over.

In a preferred embodiment it can be provided that the mathematical Function of the computers used programmed in this way is that the numerical values of weight or weight value, basic price and price of goods as bit-parallel, decade-by-decade serial Signals via a control line system for the two digit or value displays The present details of the balance according to the invention are given below with reference to the Fig. 1 to 4 explained. They show: FIG. 1 in a schematic representation, a perspective View of the weight transmission and scanning device; Fig. 2 is a state diagram the phototransistors; 3 is a block diagram, and FIG. 4 shows the arrangement of the Window discriminators in connection with the display elements.

In Fig. 1, 1 is the illumination lamp, the light of which passes through the condenser 2 is thrown onto the 3 scale. The scale 3 is on the incline weight 4 with the frame 5 attached to the inclination balance not shown in detail here and is deflected into position 3a when the inclination weight is dependent on the weight with which the balance is loaded, has moved into a position 4a, The Line graduation 6 is made sharp as an image by the object 7 in the plane of the diaphragm 8 6a shown. The aperture 8 contains three, each by a third of the division Translucent line divisions offset perpendicular to the longitudinal direction of the lines 9, 10, 11, each of which has a capacitor 12, 13, 14 with phototransistors 15, 16, 17 are downstream. The electrical states of these transistors change in Cycles of change in their lighting caused by the movement of the scale 3 by dividing the associated line division of the aperture 8 either from that of the line division 6 of the scale 3 let through light hit in phase or out of phase will.

The one from the three phototransistors 15, 16, 17 during a movement the Scale 3 supplied electrical states 15a, 16a, 17b are shown in Figo 2, where the state is denoted by L when the phototransistor is illuminated and with 0 if it is darkened 0 The arrow points to the one in the upper part the Figo 2 illustrated lighting state of the diaphragm 8. Any change in one of the three states is evaluated in the discriminator 18 as a sampling step and referred to on the direction of movement depending on the direction in the following up / down counters 19 and 20 counted.

Remains between two changes in the states of the three phototransistors the stored number of pulses constant according to the sampling steps, doh the scale 3 their position must be under the influence of a changed weight on the scales and Change at least one such piece that it leads to a change in the lighting conditions one of the three phototransistors is coming.

The discriminator 18 in Fig. 3 is provided with two outputs 21 and 22, which, if the position of the scale is scanned correctly, are the same signals in terms of both The number of counting pulses as well as the counting direction in the counters 19 and 20 are supplied. However, there is no match for functional errors. Accordingly, all are information derived from the count of the two counters 19 and 20 only Consistent if both the input variables for the counters and their mode of operation were flawless. If one denotes the weight or the weight value with G1, the or which is stored in the counter 19, the computer 24 from G1 and the via the Keypad 23 entered basic price per weight unit P calculate the product, that is the price of goods B1. The computer 25 calculates accordingly from the weight value G2 in the counter 20 and the basic price entered via the same keyboard 23 per Weight unit P the price of goods B. If there are no errors, G1 = G2 and B1 - B20 Usually2 the values of P, G and B fall one after the other as factors or as a product or via different lines. By a change of the computer program However, it can be achieved that they are synchronized serially one after the other from the computer so the numeric displays 26 and 27 control how it will result in a closed product caused by an invoice. This ensures that all necessary for the display Values are checked with only one control circuit 28-35 described in FIG which controls the control lamp 54.

The computer program required for this consists in that in the computer 24, 25 the numerical values of G1 or G2 and P can be entered and additive Entering powers of ten can be increased so that the sequence of digits of the calculated Product not only the price of the goods but also the basic price and the weight value Contains lined up.

If, for example, the maximum four-digit basic price is P = 16.83 DM / kg and that also a maximum of four-digit goods weight G1 = G2 = 1.556 kg, so the invoice (106 + 16.83) x (109 l 1.556) = 1015 + 1683 1556 026.18 with the rounding off of the fractions of pennies in the goods price of 26.18 deliver a result on the display units, that from the 13th position on, first the digits of the basic price, then that of weight and finally that of the price of goods. Generally each of the two exponents of ten can be chosen to produce a product, that the basic price, the weight and the (rounded down) amount as a series of consecutive Expresses digits.

In particular, it can be advantageous in known computer circuits be to choose the exponents so that the basic price and weight as a sequence of digits in the eight highest digits of a sixteen-digit computer output unit, the price of the goods appears as a sequence of digits in the eight lowest digits for mutual display to allow values to be added up via just one display unit or display individual values only at certain times to can.

The functional error control is now carried out according to FIG. 4 in such a way that for a preferred seven-segment numeric display between the two computer output line systems Window discriminators 28 to 34 are connected, the outputs of which via a gate circuit 35 are connected so that their signal at the output 36 is equal to 0 when between there is no difference between the two controls for the light segments, but one L signal is present if in the course of the cyclic decadic serial control of the numeric displays at least one segment control of the one numeric display 26 is different from the control of an equivalent segment of the other Numerical display or display unit 27.

The output of each of the two computers 24 and 25 consists of each seven lines 37 - 43 and 44 - 50, the parallel all segment diodes of the numeric displays 26 and 27 are supplied. Each computer also has sixteen output lines 51 and 52, which are fed to the digit segments by decade and the one Current flow and thus a lighting up of those segments cause that together optically reproduces the relevant digit in the respective decade.

The segment lines 37-43 and 44-50 are used by the computers 24 and 25 clocked synchronously with the decade lines 51 and 52, so that one after the other the digits in the digit displays light up in such a quick zy-f ¢ t: isçfwee Repetition that to the human eye of the beholder it is like a standing one Illuminated image works.

The segment lines 37-43 and 44-50 are thus in quick return assume two electrical states. They are in the vicinity of the reference potential the operating voltage, if the associated segment is not to light up, must, however at the positive potential of the operating voltage when the segment is subject to current flow should light up. The anodes of the segment light emitting diodes are therefore either on the Reference potential or at the reference potential plus the voltage drop the current-carrying diode or in the case of a short circuit in the diode, which would prevent it from shining directly to the reference potential. Faulty and Error-free states are thus distinguished as follows. Exemplary for the segment diodes 37a and 44a and UO as reference potential, UB as operating voltage, UD as voltage drop in the light-emitting diode when a current flow makes it light up, which is limited to a permissible level by the series resistors 37b and 44b the size of the anode voltage U37 and U44 U28 U35 Uo correct U28 g U35 + u wrong U28 = U35 = Uo + UD 35 -Where u-r UD is a small voltage difference, within which scatters the forward voltage of the light segment diodes.

In simplified terms, the system can be assumed to be correct if the relationship U26 = U27 + u always applies to equivalent segments, where the indices each represent a pair of segments in the two digit displays 26 and 27. The correctness of this relationship can be independent of the absolute level of the anode voltage controlled by so-called window discriminators. This is what it is is a circuit in which one input voltage is the middle position of the Determines the voltage range u in the area UO to UB and checks whether the second input voltage lies within the voltage range u as a "window". If that is the case, it will Output of circuit L, in the other, i.e. faulty case, U26 f U27 + u equal 0.

The outputs of the seven window discriminators 28-34 are above a NAND gate 35 linked together, which then and at its output 36 only delivers a 0 signal if both displays are at all times correspond to the visual representation of numbers. An L signal signals one faulty state. This signal can be used, for example, to send a To switch flip-flop 53, which turns on an error signal lamp 54.

Claims (2)

Claims ) Functionally error-proof price calculating scale with an electronic Weight transmission device to which a computer is connected, in which the Basic price is entered, which is multiplied in the calculator with the weight value and with two digital displays for the weight value, the basic price and the Goods price calculated therefrom, characterized in that to the weight transmission device parallel to the first computer (24) a second computer operating synchronously with this (25) is connected so that the computers (24, 25) are designed so that the input of weight value and basic price is increased by powers of ten, so that Weight value, basic price and price of goods are consecutive digits of the calculated Product are sequentially from the computers (24, 25) one of the two Numeric displays (26 or 27) are supplied, and that they are equivalent between each other Display elements of the two digit displays (26, 27) each have window discriminators (28, 29,30, 31, 32, 33, 34) are switched in case of a match leave a downstream gate circuit (35) unaffected and in the event of a mismatch influence the gate circuit (35) in such a way that a downstream flip-flop (53) toggles. 2. Scales according to claim 1, characterized in that the flip-flop (53) controls a connected error signal lamp (54). L e r s e i t e